秦岭南坡林地土壤有机碳密度空间分异特征

doi:10.11707/j.1001-7488.20190502

摘要/Abstract

摘要： [目的]研究陕西秦岭南坡林地土壤有机碳密度空间分异特征，为秦岭林区土壤有机碳科学管理提供理论依据。[方法]在陕西秦岭南坡不同林区（洋县长青、佛坪县龙草坪、太白县太白山、宁陕县宁东和宁陕县宁西）及立地条件（海拔、坡向、坡位和坡度）设置样地，通过调查、取样和测定，采用差异性检验分析不同立地因子对土壤有机碳密度（tC·hm^-2）的影响，并通过逐步回归分析量化各因子对土壤有机碳密度影响的相对重要性。[结果]秦岭南坡林地土壤有机碳密度均值为125.41 tC·hm^-2（52.60~307.36 tC·hm^-2），在0~10，10~30和30~60 cm土层分别为59.04，41.65和24.73 tC·hm^-2，分别占土壤有机碳总密度的47.07%，33.21%和19.72%；秦岭南坡不同林区土壤有机碳密度差异较大，表现为龙草坪（143.55 tC·hm^-2） > 宁东（138.37 tC·hm^-2） > 宁西（134.09 tC·hm^-2） > 太白山（109.29 tC·hm^-2） > 长青（90.22 tC·hm^-2）；土壤有机碳密度随海拔升高先增后降，在海拔800~1 200 m最低（平均90.24 tC·hm^-2），在海拔2 000~2 400 m最大（平均166.43 tC·hm^-2），当海拔高于2 400 m后下降（平均132.51 tC·hm^-2）；阴坡土壤有机碳密度（127.23 tC·hm^-2）稍高于阳坡（123.25 tC·hm^-2）；土壤有机碳密度随坡度增大而降低，由147.52 tC·hm^-2减至87.06 tC·hm^-2；土壤有机碳密度在下坡位（166.36 tC·hm^-2）大于中坡位（129.43 tC·hm^-2）和上坡位（77.14 tC·hm^-2）。[结论]秦岭南坡林地土壤有机碳密度存在显著的区域差异，并随海拔升高先升后降，在各海拔间和不同坡位间均差异显著（P<0.05）或极显著（P<0.01），但在阴坡与阳坡间无显著差异。逐步回归分析表明，坡位和海拔是影响土壤有机碳密度差异的主导立地因子。与我国其他主要林区相比，陕西秦岭南坡林地土壤有机碳密度处于较高水平，在我国森林土壤碳库中具有重要地位，应加强管理。

关键词: 秦岭南坡, 土壤有机碳密度, 空间分异, 立地条件, 回归分析

Abstract: [Objective] The patterns of spatial variation of the density of soil organic carbon (SOC) in forest land was studied on the southern slope of Qinling Mountains in Shaanxi Province, which provided a theoretical basis for the scientific management of SOC in Qinling Mountains.[Method]Sample plots were set up in different forest regions (Changqing of Yang County, Longcaoping of Foping County, Taibai Mountain of Taibai County, Ningdong of Ningshan County and Ningxi of Ningshan County) and different site conditions (elevation, slope aspect, slope position and slope) on the southern slope of the Qinling Mountains. Investigation, sampling and determination were carried out. Difference tests were used to analyze the effects of different site factors on SOC density (tC·hm^-2). Stepwise regression analysis was employed to quantify the relative importance of each factor on the variation of SOC density.[Result]The average SOC density was 125.41 tC·hm^-2(52.60-307.36 tC·hm^-2)on the southern slope of Qinling Mountains, which were 59.04, 41.65, and 24.73 tC·hm^-2 in 0-10, 10-30, and 30-60 cm soil layers respectively, accounting for 47.07%, 33.21% and 19.72% of the total SOC density, respectively. The SOC density varied greatly among different regions on the southern slope of Qinling Mountains, showing Longcaoping of Foping County (143.55 tC·hm^-2), Ningdong of Ningshan County (138.37 tC·hm^-2), Ningxi of Ningshan County (134.09 tC·hm^-2), Taibai Mountain of Taibai County (109.25 tC·hm^-2), and Changqing of Yang County (90.22 tC·hm^-2). The SOC density firstly increased and then decreased with increasing altitude. The SOC density (90.24 tC·hm^-2) was the lowest at 800-1 200 m above sea level, and the SOC density (166.43 tC·hm^-2) was the highest at the 2 000-2 400 m above sea level. When the altitude was higher than 2 400 m, the SOC density decreased, with an average of 132.51 tC·hm^-2. The SOC density (127.23 tC·hm^-2) of shady slope was slightly higher than that (123.25 tC·hm^-2) of sunny slope. The SOC density decreased from 147.52 to 87.06 tC·hm^-2 with the increase of slope. The SOC density in the down slope (166.36 tC·hm^-2) was higher than those in the middle (129.43 tC·hm^-2) and up-slope (77.14 tC·hm^-2).[Conclusion] The variations of SOC density among different forest regions were significant. The trend was increased first and then decreased with the increase of elevation. Significant differences (P<0.05) or extremely significant differences (P<0.01)of SOC density appeared in elevation ranges and different slope position. However, the difference of SOC density was not significant between shady slope and sunny slope. Stepwise regression analysis showed that the slope position and elevation were the dominant topographic factors that affect the SOC density. Compared with other forest areas in China, the SOC density in forest land on the southern slope of Qinling Mountains was at a higher level in the country. The SOC on the southern slope of Qinling Mountains plays an important role in the soil carbon pool of forest ecosystem in China and the management should be strengthened.

Key words: southern slope of Qinling Mountains, soil organic carbon density, spatial characterization, site conditions, analysis of stepwise regression

中图分类号:

S714

卫玮, 党坤良. 秦岭南坡林地土壤有机碳密度空间分异特征[J]. 林业科学, 2019, 55(5): 11-19.

Wei Wei, Dang Kunliang. Spatial Variation of the Density of Soil Organic Carbon in Forest Land on the Southern Slope of Qinling Mountains[J]. Scientia Silvae Sinicae, 2019, 55(5): 11-19.

参考文献

陈海滨, 陈志彪, 陈志强. 2010. 南方红壤侵蚀区地形对土壤有机质空间分布的影响——以长汀县河田地区为例. 福建农业学报, 25(3):369-373.
(Chen H B, Chen Z B, Chen Z Q. 2010. Impact of topography on spatial distribution of organic matters in red eroded soil in south China-a case study at Hetian in Changting County. Fujian Journal of Agricultural Sciences, 25(3):369-373.[in Chinese])
陈亮中. 2007. 三峡库区主要森林植被类型土壤有机碳研究. 北京:北京林业大学硕士学位论文.
(Chen L Z. 2007. Studies on soil carbon under main forest vegetation types in the Three-Gorges Reservoir Area. Beijing:MS thesis of Beijing Forestry University.[in Chinese])
郭建明, 胡理乐, 林伟,等. 2010. 秦岭太白红杉林土壤有机碳密度研究. 环境科学研究, 23(12):1464-1469.
(Guo J M, Hu L L, Lin W, et al. 2010. Soil organic carbon density of Larix chinensis Beissen forest in Mt. Taibai in Qinling. Research of Environmental Sciences, 23(12):1464-1469.[in Chinese])
郭晓伟. 2015. 尖峰岭热带雨林土壤有机碳密度空间分布规律. 北京:中国林业科学研究院硕士学位论文.
(Guo X W. 2015. Spatial distribution of soil organic carbon density in tropical rainforest of Jianfengling, Hainan Island. Beijing:MS thesis of Chinese Academy of Forestry.[in Chinese])
郭晓伟, 骆土寿, 李意德, 等. 2015. 海南尖峰岭热带山地雨林土壤有机碳密度空间分布特征. 生态学报, 35(23):7878-7886.
(Guo X W, Luo T S, Li Y D, et al. 2015. Spatial distribution characteristics of soil organic carbon density in a tropical mountain rainforest of Jianfengling, Hainan Island, China. Acta Ecologica Sinica, 35(23):7878-7886.[in Chinese])
侯琳, 雷瑞德, 王得祥, 等. 2008. 秦岭火地塘天然次生油松林土壤有机碳的特征. 西北农林科技大学学报:自然科学版, 36(8):156-160.
(Hou L, Lei R D, Wang D X, et al. 2008. Traits of soil organic carbon density in Pinus tabulaeformis secondary forest at Huoditang valley forest area in Qinling Mountains. Journal of Northwest A & F University:Natural Science Edition, 36(8):156-160.[in Chinese])
侯琳, 雷瑞德, 王得祥,等. 2009. 秦岭火地塘林区油松群落乔木层的碳密度. 东北林业大学学报, 37(1):23-24.
(Hou L, Lei R D, Wang D X, et al. 2009. Carbon density of arbor layer in Pinus tabulaeformis community in Huoditang Forest Region of Qinling Mountains. Journal of Northeast Forestry University, 37(1):23-24.[in Chinese])
姜航, 高菲, 崔晓阳. 2015. 帽儿山次生林区土壤有机碳储量及地形因子的影响. 森林工程, 31(3):15-20.
(Jiang H, Gao F, Cui X Y. 2015. Soil organic carbon storage and effects of topographical factors of the secondary forest region of Maoer Mountains. Forest Engineering, 31(3):15-20.[in Chinese])
李龙, 姚云峰, 秦富仓,等. 2014. 赤峰市小流域地形因子对土壤有机碳密度的影响. 中国水土保持, (3):43-46.
(Li L, Yao Y F, Qin F C, et al. 2014. Effects of topographical factors on soil organic carbon density in small watershed of Chifeng City. Soil and Water Conservation in China, (3):43-46.[in Chinese])
李旭, 刘钊, 周伟,等. 2016. 云南楚雄恐龙河保护区绿孔雀春季栖息地选择和空间分布. 南京林业大学学报:自然科学版, 40(3):87-93.
(Li X, Liu Z, Zhou W, et al. 2016. Habitat selection and spatial distribution of green peafowl (Pavo muticus) in Konglonghe Natural Reserve of Chuxiong, Yunnan Province. Journal of Nanjing Forestry University:Natural Science Edition, 40(3):87-93.[in Chinese])
刘康, 马乃喜, 胥艳玲, 等. 2004. 秦岭山地生态环境保护与建设. 生态学杂志, 23(3):157-160.
(Liu K, Ma N X, Xu Y L, et al. 2004. Protection and construction of eco-environment in Qinling Mountains area. Chinese Journal of Ecology, 23(3):157-160.[in Chinese])
刘鹏飞. 2013. 西双版纳地区热带森林土壤碳储量研究. 北京:中国科学院大学硕士学位论文.
(Liu P F. 2013. Soil carbon storage of tropical forests in Xishuangbanna, southwest China. Beijing:MS thesis of University of Chinese Academy of Sciences.[in Chinese])
刘伟, 程积民, 陈芙蓉,等. 2011. 黄土高原中部草地土壤有机碳密度特征及碳储量. 草地学报, 19(3):425-431.
(Liu W, Cheng J M, Chen F R, et al. 2011. Characteristic of organic carbon density and organic carbon storage in the natural grassland of center Loess Plateau. Acta Agrestia Sinica, 19(3):425-431.[in Chinese])
罗伟祥, 刘广全, 李嘉珏. 2007. 西北主要树种培育技术. 北京:中国林业出版社, 238-245.
(Luo W X, Liu G Q, Li J J. 2007. Cultivation techniques of main tree species in Northwest China. Beijing:China Forestry Publishing House, 238-245.[in Chinese])
舒洋, 魏江生, 周梅, 等. 2013. 乌拉山天然油松林土壤碳密度空间异质性研究. 土壤通报, 44(6):1304-1307.
(Shu Y, Wei J S, Zhou M, et al. 2013. Study on spatial heterogeneity of Wulashan natural Pinus tabulaeformis forest soil carbon density. Chinese Journal of Soil Science, 44(6):1304-1307.[in Chinese])
唐朋辉, 党坤良, 王连贺, 等. 2016. 秦岭南坡红桦林土壤有机碳密度影响因素. 生态学报, 36(4):1030-1039.
(Tang P H, Dang K L, Wang L H, et al. 2016. Factors affecting soil organic carbon density in Betula albo-sinensis forests on the southern slope of the Qinling Mountains. Acta Ecologica Sinica, 36(4):1030-1039.[in Chinese])
魏亚伟, 于大炮, 王清君, 等. 2013. 东北林区主要森林类型土壤有机碳密度及其影响因素. 应用生态学报, 24(12):3333-3340.
(Wei Y W, Yu D P, Wang Q J, et al. 2013. Soil organic carbon density and its influencing factors of major forest types in the forest region of Northeast China. Chinese Journal of Applied Ecology, 24(12):3333-3340.[in Chinese])
许明祥, 刘国彬, 赵允格. 2011. 黄土丘陵区土地利用及环境因子对土壤质量指标变异性的影响. 应用生态学报, 22(2):409-417.
(Xu M X, Liu G B, Zhao Y G. 2011. Effects of land use and environmental factors on the variability of soil quality indicators in hilly Loess Plateau region of China. Chinese Journal of Applied Ecology, 22(2):409-417.[in Chinese])
薛志婧, 马露莎, 安韶山, 等. 2015. 黄土丘陵区小流域尺度土壤有机碳密度及储量. 生态学报, 35(9):2917-2925.
(Xue Z J, Ma L S, An S S, et al. 2015. Soil organic carbon density and stock at the catchment scale of a hilly region of the Loess Plateau. Acta Ecologica Sinica, 35(9):2917-2925.[in Chinese])
杨万勤, 邓仁菊, 张健. 2007. 森林凋落物分解及其对全球气候变化的响应. 应用生态学报, 18(12):2889-2895.
(Yang W Q, Deng R J, Zhang J. 2007. Forest litter decomposition and its responses to global climate change. Chinese Journal of Applied Ecology, 18(12):2889-2895.[in Chinese])
杨晓梅, 程积民, 孟蕾,等. 2010. 子午岭不同林地土壤有机碳及养分储量特征分析. 水土保持研究, 17(3):130-134.
(Yang X M, Cheng J M, Meng L, et al. 2010. Analysis of soil organic carbon and nutrients storages in different forests in Ziwuling. Research of Soil and Water Conservation, 17(3):130-134.[in Chinese])
张鹏, 张涛, 陈年来. 2009. 祁连山北麓山体垂直带土壤碳氮分布特征及影响因素. 应用生态学报, 20(3):518-524.
(Zhang P, Zhang T, Chen N L. 2009. Vertical distribution patterns of soil organic carbon and total nitrogen and related affecting factors along northern slope of Qinling Mountains. Chinese Journal of Applied Ecology, 20(3):518-524.[in Chinese])
张苏峻, 黎艳明, 周毅, 等. 2010. 粤西桉树人工林土壤有机碳密度及其影响因素. 中南林业科技大学学报:自然科学版, 30(5):22-28.
(Zhang S J, Li Y M, Zhou Y, et al. 2010. Distribution patterns of soil organic carbon density in western Guangdong and its affecting factors. Journal of Central South University of Forestry & Technology:Natural Science Edition, 30(5):22-28.[in Chinese])
赵德怀. 2006. 佛坪自然保护区发展史记. 杨凌:西北农林科技大学出版社, 11
(Zhao D H. 2006. Development history of Foping Nature Reserve. Yangling:Northwest Agriculture and Forestry University Press, 11[in Chinese])
赵明月, 赵文武, 钟莉娜. 2014. 土地利用和环境因子对表层土壤有机碳影响的尺度效应——以陕北黄土丘陵沟壑区为例. 生态学报, 34(5):1105-1113.
(Zhao M Y, Zhao W W, Zhong L N. 2014. Scale effect analysis of the influence of land use and environmental factors on surface soil organic carbon:a case study in the hilly and gully area of Northern Shaanxi Province. Acta Ecologica Sinica, 34(5):1105-1113.[in Chinese])
赵庆云, 宋松涛, 杨贵名,等. 2014. 西北地区暴雨时空变化及异常年夏季环流特征. 兰州大学学报:自然科学版, 50(4):517-522.
(Zhao Q Y, Song S T, Yang G M, et al. 2014. Spatial and temporal variations of torrential rain over Northwest China and general circulation anomalies in summer. Journal of Lanzhou University:Natural Sciences, 50(4):517-522.[in Chinese])
钟吉安. 2009. 大巴山林区主要人工林土壤有机碳密度的研究. 四川林勘设计, (2):23-26.
(Zhong J A. 2009. Study on soil organic carbon density of main plantation in the Dabashan Forest Areas. Sichuan Forestry Exploration and Design, (2):23-26.[in Chinese])
周鑫, 姜航, 孙金兵, 等. 2016. 地形因子和物理保护对张广才岭次生林土壤有机碳密度的影响. 北京林业大学学报, 38(4):94-106.
(Zhou X, Jiang H, Sun J B, et al. 2016. Soil organic carbon density as affected by topography and physical protection factors in the secondary forest area of Zhangguangcai Mountains, northeast China. Journal of Beijing Forestry University, 38(4):94-106.[in Chinese])
De Deyn G B, Cornelissen J H, Bardgett R D. 2008. Plant functional traits and soil carbon sequestration in contrasting biomes. Ecology Letters, 11(5):516-531.
Hao Y, Lal R, Owens L B, et al. 2002. Effect of cropland management and slope position on soil organic carbon pool at the North Appalachian Experimental Watersheds. Soil & Tillage Research, 68(2):133-142.
Kitchen N R, Drummond S T, Lund E D, et al. 2003. Soil electrical conductivity and topography related to yield for three contrasting soil-crop systems. Agronomy Journal, 95(3):483-495.
Liao J D, Boutton T W, Jastrow J D. 2006. Organic matter turnover in soil physical fractions following woody plant invasion of grassland:evidence from natural ¹³C and ¹⁵N. Soil Biology & Biochemistry, 38(11):3197-3210.
Martin M P, Wattenbach M, Smith P, et al. 2011. Spatial distribution of soil organic carbon stocks in France. Biogeosciences, 8(5):1053-1065.
Pan G, Pete S, Pan W. 2009. The role of soil organic matter in maintaining the productivity and yield stability of cereals in China. Agriculture Ecosystems & Environment, 129(1-3):344-348.
Sharma C M, Gairola S, Baduni N P, et al. 2011. Variation in carbon stocks on different slope aspects in seven major forest types of temperate region of Garhwal Himalaya, India. Journal of Biosciences, 36(4):701-708.
Tan Z X, Lal R, Smeck N E, et al. 2004. Relationships between surface soil organic carbon pool and site variables. Geoderma, 121(3/4):187-195.
Ziadat F M. 2005. Analyzing digital terrain attributes to predict soil attributes for a relatively largearea. Soil Science Society of America Journal, 69(5):1590-1599.

[1]	王志康, 许晨阳, 耿增超, 刘莉丽, 侯琳, 杜璨, 王强, 吕东唯. 基于扣除根系体积新方法的秦岭辛家山2种林分土壤有机碳密度特征[J]. 林业科学, 2019, 55(6): 133-141.
[2]	胡珍珠, 潘存德, 潘鑫, 朱白雪. 基于光谱水分指数的核桃叶片含水量估算模型[J]. 林业科学, 2016, 52(12): 39-49.
[3]	白玉锋, 陈超群, 徐海量, 张广朋, 张沛, 凌红波. 塔里木河下游荒漠植被地上生物量空间分布与地下水埋深关系[J]. 林业科学, 2016, 52(11): 1-10.
[4]	陈存, 丁昌俊, 苏晓华, 黄秦军. 欧美杨纤维含量构成因素的相关和通径分析[J]. 林业科学, 2016, 52(11): 124-133.
[5]	彭逸生, 李皓宇, 曾瑛, 彭盛华, 肖寒. 广东韩江三角洲地区红树林群落现状及立地条件[J]. 林业科学, 2015, 51(12): 103-112.
[6]	白超;张文辉;雷亚芳. 秦岭北坡2种类型栓皮栎软木生长及特性[J]. 林业科学, 2013, 49(4): 62-69.
[7]	王强;胡海清. 基于岭回归和人工神经网络估测森林可燃物负荷量[J]. 林业科学, 2012, 48(9): 108-114.
[8]	吕瑞恒;李国雷;刘勇;贾黎明;江萍;林娜. 不同立地条件下华北落叶松叶凋落物的分解特性[J]. 林业科学, 2012, 48(2): 31-37.
[9]	杨忠;黄安民;江泽慧. 近红外光谱结合回归分析预测法判别木材的生物腐朽[J]. 林业科学, 2012, 48(10): 120-124.
[10]	秦树高;吴斌;张宇清;张天勇. 锦鸡儿林草带状复合系统细根空间分异特征[J]. 林业科学, 2011, 47(7): 42-49.
[11]	薛瑶芹;张文辉;周建云;杨保林;周民建;. 秦岭南坡不同生境条件下栓皮栎伐桩萌芽特性[J]. 林业科学, 2011, 47(7): 57-64.
[12]	王秀花;马丽珍;马雪红;陈柳英;周志春. 木荷人工林生长和木材基本密度[J]. 林业科学, 2011, 47(7): 138-144.
[13]	吴若菁;庄捷;陈清松;陈文萍. 铅胁迫下马尾松微核率与生理指标变化的相关分析[J]. 林业科学, 2010, 46(8): 78-83.
[14]	徐文科蔡体久琚存勇. 基于RS和GIS的毛乌素沙地荒漠化程度定量估测[J]. 林业科学, 2007, 43(05): 48-53.
[15]	叶建仁廖太林;. 松树枯梢病发生的立地条件及其主要诱因分析[J]. 林业科学, 2006, 42(09): 79-82.